DE102014225908A1 - glow plug - Google Patents

Abstract

The invention relates to a glow plug (10) for a self-igniting internal combustion engine and to a method for producing a glow plug (10). The glow plug (10) has a housing (20) and an at least partially in the housing (20) arranged terminal contact (22). The glow plug (10) also has an at least indirectly connected to the housing (20) glow tube (30), wherein the glow tube (30) at a housing (20) facing away from end (31) and filled with an insulating powder (39) is. Arranged in the glow tube (30) is a heating coil (32) which can be connected to the connection contact (229). An inner diameter (33) of the heating coil (32) forms, at least in sections, a cavity (34), wherein in the cavity (34) a powder compact (35) of an electrically insulating powder (36, 39) is inserted.

Description

State of the art

The present invention relates to a glow plug for a self-igniting internal combustion engine according to claim 1 and a method for producing a glow plug according to claim 10.

In self-igniting internal combustion engines glow plugs are provided to heat the individual combustion chambers of the engine so far that a fuel injected into the combustion chamber safely ignites under the compression of the piston moving upward. The glow plug is exposed to the sudden heating in the combustion chamber and a corresponding pressure wave. Furthermore, the glow plug is exposed to vibration during operation of the internal combustion engine. It must be ensured under all operating conditions that the heating coil of the glow plug is electrically insulated except for the intended contact areas of the housing to avoid electrical short circuit or heating of the glow plug at an undefined point. Furthermore, it must be ensured that an electrical connection between terminal contact and heating coil remains stable and durable, but is flexible enough not to be destroyed by the vibration and pressure waves described.

For this purpose, the heating coil in the region of the glow tube is stabilized in that in the glow tube, an insulating powder is filled and compressed, which stabilizes the one hand, the position of the heating coil, on the other hand creates a secure electrical insulation between heating coil and housing. From the EP 1 471 307 a glow plug is known in which in a cavity formed by the heating coil, a ceramic core is used, which is electrically insulated and has a thermal conductivity which is lower than the thermal conductivity of the insulating powder, which is filled in the space between the heating coil and Glührohrwand. Although this solution increases the power output of a glow plug, since less heat is lost inside, the hard ceramic core has disadvantages in terms of damping of pressure waves and vibrations.

Furthermore, glow plugs are known from the prior art, in which a single coil combines the properties of a heating coil and a control coil. In the known structure of such a glow plug, the heating and control coil are connected to the metallic glow tube, then filled with a thermally conductive and electrically insulating powder, sealed and compacted by a so-called rotary swaging to a certain extent. The rotary kneading is done mainly for compacting the powder inside the radiator to ensure good heat conduction from the heating coil to the outer surface of the glow tube.

Disclosure of the invention

An object of the invention is therefore to provide a glow plug, which is characterized by a simple production and overcomes the disadvantages known from the prior art.

The glow plug according to the invention with the features of claim 1 has the advantage that an interior of the heating coil at least partially forms a cavity, wherein in the cavity a powder compact of an electrically insulating powder is used. Compared with the prior art, the powder compact has the advantage that the powder in the cavity between the heating coil does not have to be compacted subsequently by a time-consuming and costly process, in which there is also the risk that the wire of the heating coil during the compression of the powder deformed or even damaged. When using highly ductile materials for the heating coil, the wire diameter may increase in known from the prior art glow plugs and the original round wire then become oval. As a result of the wire deformation are shorted turns of the heating coil, short circuit between the glow tube and heating coil, and an undesirable decrease in the electrical resistance of the wire of the filament known. This is prevented by the proposed construction. Furthermore, the powder compact is much more flexible with respect to a solid ceramic body, and if necessary can be broken up again into powder by the wire of the heating coil. As a result, the deformation of the heating coil is significantly reduced and the life of the glow plug significantly improved.

The measures specified in the dependent claims advantageous refinements and improvements of the independent claim glow plug are possible.

An advantageous development is that the cavity between the heating coil and the powder compact are cylindrical. Although other shapes, in particular 6eckige, 8eckige or oval contours of the powder compact are possible, so is a cylindrical shape, and a cylindrical winding of the wire of the heating coil, particularly easy to manufacture.

A further advantageous development is that the powder compact has an outer contour, in particular an outer diameter, which is smaller than or equal to an inner contour the heating coil is. The powder compact should be easy to insert in the cavity between the heating coil and pull when inserting no deformation or damage to the heating coil with it. There is a clearance fit, or a transition fit, in which both parts are the same size, advantageous because it can be a simple and largely force-free insertion of the powder compact realized.

A further advantageous development is that the powder compact has the same length as the cavity formed by the heating coil. Thereby, the heating coil is supported and stabilized over the entire length of the cavity, so that the heating coil is reduced by the powder compact in their flexibility and suffers less deformation during filling and compression of the insulating powder.

Alternatively, it is provided that the powder compact is designed in several parts and in this case comprises a plurality of powder tablets. These powder tablets can be used instead of a one-piece powder compact in the cavity. Alternatively, it is also possible to arrange thin insulation bodies between two powder tablets which increase the stability between the powder compacts or are designed as guides for the individual powder tablets. In addition, several powder tablets have the advantage that they can be produced more easily from a certain length, since the forces required for pressing a one-piece powder compact with the length of the powder compact rise.

Furthermore, it is advantageously provided that the powder compact and the insulating powder consist of the same base material. If the powder compact and the insulating powder consist of the same material, then the risk of confusion of the substances in the production process is excluded. In addition, such a solution leads to permanently the same thermal and electrical conductivities, even if the powder compact should be damaged over the lifetime of the glow plug and mixed with the insulation powder.

Furthermore, it is advantageously provided that the powder compact has a lower thermal conductivity than the insulating powder. As a result, the heat transfer is promoted by the heating coil to the glow tube, resulting in a faster heating of the glow plug and an overall lower power consumption.

It is particularly advantageous if the powder compact and the insulating powder consist of different base materials. By different starting materials with different thermal conductivity can easily realize a glow plug, in which the heat transfer is favored by the heating coil to glow tube.

Alternatively or additionally, it is advantageously provided that the powder compact and the insulating powder have different particle sizes in the base material. It is particularly preferred if the powder compact consists of a coarse-grained base material as the insulating powder.

A further advantageous development consists in that the heating coil has a reduced diameter at its end facing the closed end of the glow tube, so that an end face of the powder compact can rest on this reduced diameter such that the reduced diameter forms an axial stop for the powder compact , Alternatively, the powder compact can also be clamped by the reduced diameter on the lateral surface, but an axial stop is gentler material.

Brief description of the drawings

The invention is explained in more detail in the following description with reference to exemplary embodiments illustrated in the drawings. Like components or components with the same function are identified by the same reference numerals. Show it:

1 the structure of a glow plug according to the prior art

1a the structure of a combustion chamber side portion of a glow plug with monovel of the prior art.

2 a powder compact according to the invention for insertion into a cavity formed by the heating coil

Description of the embodiments

1 shows a glow plug 10 according to the prior art. The glow plug 10 has a housing 20 in which a connection contact 22 is arranged. The glow plug 10 has a glow tube 30 on. In the glow tube 30 are a rule coil 3 and with the rule coil 3 connected heating coil 32 arranged. Alternatively, the heating coil 32 and the rule coil 3 also be designed as a single helix, a so-called Monowendel. The heating coil 32 is with a closed end 31 of the glow tube 30 connected, with the closed end 31 the housing 20 turned away. In the glow tube 30 is an insulation powder 39 filled, which is electrically insulating, but thermally conductive. Between a the case 20 facing the end of the glow tube 30 and the connection contact 22 is a radiator seal 6 arranged, which provides electrical insulation between terminal bolts 22 and the glow tube 30 forms. The connecting bolt 22 is designed as a positive contact, while that with the housing 20 electrically conductive glow tube 30 a negative contact of the glow plug 10 formed. For electrical contacting of the glow plug 10 are at one of the glow tube 30 opposite end of the housing between housing 20 and connection contact 22 a housing seal 8th and an isolation disc 9 provided, as well as a round plug 5 over which the terminal contact 22 can be electrically controlled. It is the isolation disc 9 an electrical insulation between round plug 5 and housing 20 represents.

In 1a is the combustion chamber side section of a glow plug also known from the prior art 10 with a so-called Monowendel 132 shown. The Monovendel 132 functionally combines the tasks of the heating coil 32 and the rule coil 3 in a single component. The Monovendel 132 is at her closed end 31 of the glow tube 30 facing end portion with the glow tube 30 connected, and with their closed end 31 remote end region with the connection contact 22 connected. In the following statements and claims, the term of the heating coil 32 be understood that with a glow plug, which is a Monowendel 132 this also under the term heating coil 32 falls.

In the manufacture of a glow plug according to the invention 10 will be like in 2 initially shown from a thermally conductive, but electrically insulating material a powder compact 35 produced. The powder compact 35 gets into one of the heating coil 32 and possibly of the control coil 3 formed cavity 34 used. The length correspond 43 and the outside diameter 42 of the powder compact 35 in about the length or the inner diameter 33 of the cavity 34 , The inner contour 37 the heating coil 32 forms a boundary of the cavity 34 , The powder compact 35 supports itself with his face 44 at a reduced diameter at one end closed 31 of the glow tube 30 facing the end 48 which has an axial stop 49 for the powder compact 35 forms. After that, the glow tube 30 with insulation powder 39 filled and compacted in another production step. Subsequently, the heating coil 32 either directly or by means of the control coil 3 with the connection contact 22 connected. This manufacturing process reduces the burden on the wire of the heating coil 32 when compacting the insulation powder 39 and thus causes the glow plug 10 has a longer life. Further, by the powder compact 35 a particularly good thermal conductivity in the interior of the heating coil 32 scored, since this point in a conventional compression of insulating powder 39 not so easily accessible and a compacting through the wire of the heating coil 32 is difficult.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1471307 [0003]

Claims (14)

Glow plug ( 10 ) for a self-igniting internal combustion engine, with a housing ( 20 ), at least partially arranged in the housing terminal contact ( 22 ) and at least indirectly with the housing ( 20 ) connected glow tube ( 30 ), wherein the glow tube ( 30 ) on a housing ( 20 ) facing away from the end ( 31 ) and with an insulating powder ( 39 ), and wherein in the glow tube ( 30 ) a heating coil ( 32 ) is arranged, which with the connection contact ( 22 ), characterized in that an inner diameter ( 33 ) the heating coil ( 32 ) at least in sections a cavity ( 34 ), wherein in the cavity ( 34 ) a powder compact ( 35 ) an electrically insulating powder ( 36 . 39 ) is used. Glow plug ( 10 ) according to claim 1, characterized in that the cavity ( 34 ) and the powder compact ( 35 ) are cylindrical. Glow plug ( 10 ) according to claim 1 or 2, characterized in that the powder compact ( 35 ) an outer contour ( 41 ), in particular an outer diameter ( 42 ), which is smaller than or equal to an inner contour ( 37 ) the heating coil ( 32 ). Glow plug ( 10 ) according to one of claims 1 to 3, characterized in that the powder compact ( 35 ) the same length as the cavity formed by the heating coil ( 34 ) having. Glow plug ( 10 ) according to one of claims 1 to 4, characterized in that the powder compact ( 35 ) is formed in several parts, and several pressed powder tablets ( 38 ). Glow plug according to one of claims 1 to 5, characterized in that the powder compact ( 35 ) consists of a thermally conductive powder. Sheath-type glow plug according to Claim 6, characterized in that the thermally conductive powder is magnesium oxide (MgO), aluminum oxide (Al ₂ O ₃ ), silicon nitrite (Si ₃ N ₄ ), silicon carbide (SiC), aluminum nitrite (AlN), zirconium oxide (ZrO ₂ ) or a mixture of these substances is. Glow plug according to one of claims 1 to 7, characterized in that the powder compact ( 35 ) a lower thermal conductivity than the insulating powder ( 39 ) having. Glow plug according to claim 1 to 8, characterized in that the powder compact ( 35 ) and the insulation powder ( 39 ) consist of different base materials. Glow plug according to one of claims 1 to 8, characterized in that the powder compact ( 35 ) and the insulation powder ( 39 ) consist of the same basic material. Glow plug according to claim 1 to 10, characterized in that the powder compact ( 35 ) and the insulation powder ( 39 ) have different particle sizes in the base material, in particular that the powder compact ( 35 ) of a larger, average particle size than the insulating powder ( 39 ) having. Glow plug according to one of claims 1 to 11, characterized in that the heating coil ( 32 ) at its closed end ( 31 ) of the glow tube ( 20 ) facing end ( 48 ) has a reduced diameter, so that an end face ( 44 ) of the powder compact ( 35 ) rests on this reduced diameter, such that the reduced diameter an axial stop ( 49 ) for the powder compact ( 35 ). Method for producing a glow plug ( 10 ) with a housing ( 20 ), whereby a connection contact ( 22 ) at least in sections in the housing ( 20 ) is arranged and wherein at least indirectly a glow tube ( 30 ) with a closed end ( 31 ) with the housing ( 20 ), and wherein a heating coil ( 32 ) in the glow tube ( 30 ) is arranged, characterized in that from an insulation powder ( 36 . 39 ) a powder compact ( 35 ), which before filling the glow tube ( 30 ) with an insulating powder ( 39 ) and before connecting the heating coil ( 32 ) with the connection contact ( 22 ) into one of an inner diameter ( 33 ) the heating coil ( 32 ) limit cavity ( 34 ) is used. Method for producing a glow plug according to claim 13, characterized in that the insulating powder ( 39 ) after inserting the powder compact ( 35 ) in the cavity ( 34 ) in the glow tube ( 30 ) is filled and compacted.

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